Increase in testicular androgen receptor during sexual maturation in the rat

Androgen receptor concentration was measured by exchange with 3H-dimethylnortestosterone (DMNT) in cytosol and nuclear extracts from testes of rats 15-90 days of age. Dissociation kinetics verified the necessity of an extended incubation (86 h) for maximum exchange at 4 degrees C. Nuclear androgen receptor concentration per mg DNA decreased between 15 and 25 days of age, from 375 to 146 fmol per mg DNA, then increased to 584 fmol per mg DNA at 90 days. Testicular receptor content also increased between 25 and 90 days of age. Cytosol receptor concentration patterns were similar to nuclear androgen receptor patterns. The affinity of the receptor for the ligand did not change with age (mean Kd = 0.88 nM). No significant difference in androgen receptor concentration per cell was detected between cultured peritubular cells from animals 25 and 45 days of age. Androgen receptor concentrations in freshly isolated peritubular cells could not be determined. There also was no difference in receptor concentration per cell in a Leydig cell-enriched fraction from animals between 25 and 45 days of age. Although androgen receptor concentrations per Sertoli cell increased between 15 and 35 days of age, the increase in Leydig cell number over the same period probably accounted for approximately 75% of the increase in receptor per testis between 25 and 45 days of age.     

List of publications on human biometeorology in Czechoslovakia (period 1920–1960)

International Journal of Biometeorology -     

Involvement of protein phosphorylation in the sensitivity of photosystem II to strong illumination

Four types of differently phosphorylated hylakoids isolated from field grown spinach ( Spinacia oleracea L.) were tested for the sensitivity of photosystem II (PSII) to photoinactivation. Phosphorylation of light-harvesting II complexes (LHCII) protected PSII electron transfer from photoinhibitory damage, while the phosphorylation of the PSII core polypeptides slightly accelerated the decline of electron transfer during high irradiance treatment. Dephosphorylation of the CP43 apoprotein and PsbH protein by an alkaline phosphatase resulted in an extreme sensitivity of the thylakoids to strong illumination. The PSII photoinactivation of thylakoids with the impaired oxygen-evolving complex was found to be independent of phosphorylation.
The thylakoids of the thermophilic cyanobacterium Synechococcus elongates were used in order to compare the plants with an organism where LHCII complexes are missing and the PSII core proteins are not phosphorylated.     

Genetics of sex determination in flowering plants

Most flowering plant species are hermaphroditic, but a small number of species in most plant families are unisexual (i.e., an individ-ual will produce only male or female gametes). Because species with unisexual flowers have evolved repeatedly from hermaphroditic progenitors, the mechanisms controlling sex determination in flowering plants are extremely diverse. Sex is most strongly determined by genotype in all species but the mechanisms range from a single controlling locus to sex chromosomes bearing several linked locirequired for sex determination. Plant hormones also influence sex expression with variable effects from species to species. Here, we review the genetic control of sex determination from a number of plant species to illustrate the variety of extant mechanisms. We emphasize species that are now used as models to investigate the molecular biology of sex determination. We also present our own investigations of the structure of plant sex chromosomes of white campion (Silene latifolia - Melan-drium album). The cytogenetic basis of sex determination in white campion is similar to mammals in that it has a male-specific Y-chromosome that carries dominant male determining genes. If one copy of this chromosome is in the genome, the plant is male. Otherwise it is female. Like mammalian Y-chromosomes, the white campion Y-chromosome is rich in repetitive DNA. We isolated repetitive sequences from microdissected Y-chromosomes of white campion to study the distribution of homologous repeated sequences on the Y-chromosome and the other chromosomes. We found the Y to be especially rich in repetitive sequences that were generally dispersed over all the white campion chromosomes. Despite its repetitive character, the Y-chromosome is mainly euchromatic. This may be due to the relatively recent evolution of the white campion sex chromosomes compared to the sex chromosomes of animals. © 1994 Wiley-Liss, Inc.     

Coordinate estrogen-regulated instability of serum protein-coding messenger RNAs in Xenopus laevis

Estrogen causes the cytoplasmic destabilization of albumin and gamma-fibrinogen mRNA in Xenopus laevis liver. The purpose of the present study was to determine whether mRNA destabilization is a generalized phenomenon in response to estrogen, or whether this process is restricted to a particular class of mRNAs. To address this, we have expanded our bank of serum protein-coding cDNA clones to include transferrin, the second protein of inter-alpha-trypsin inhibitor and clone 12B, for which there is no mammalian homolog. Together with albumin and gamma-fibrinogen, these represent more than 85% of the mRNAs encoding liver secreted proteins. Estrogen administration to male Xenopus or to liver explant cultures causes the generalized disappearance of all of these mRNAs. In contrast, estrogen has no effect on actin, ferritin, or poly(A)-binding protein mRNA, all of which encode intracellular proteins. We have previously demonstrated that albumin mRNA is degraded in both messenger ribonucleoprotein and polysome fractions. Sucrose gradient analysis demonstrates the same pattern for degradation of all other serum protein-coding mRNAs. Estrogen has no effect on the amounts or gradient distribution of actin, ferritin, or poly(A)-binding protein mRNA. We conclude that regulated destabilization of mRNAs encoding secreted proteins is a generalized phenomenon in response to estrogen stimulation of Xenopus liver.